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1. Waves and Particles

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Title: 1. Waves and Particles


1
1. Waves and Particles 2. Interference of
Waves 3. Wave Nature of Light
1. Double-Slit Experiment reading Chapter
22 2. Single-Slit Diffraction reading Chapter
22 3. Diffraction Grating reading Chapter 22

2
Chapter 22
Light as a Wave Wave Optics
3
The Nature of Light Particle or Waves?
WAVE?
PARTICLES?
4
The Nature of Light Particle or Waves?
  • Before the beginning of the nineteenth century,
    light was considered to be a stream of particles
  • Newton was the chief architect of the particle
    theory of light
  • He believed the particles left the object and
    stimulated the sense of sight upon entering the
    eyes
  • But he was wrong. LIGHT IS A WAVE.

5
The Nature of Light Particle or Waves?
How can we distinguish between particles and
waves?
For waves we have interference, for particles
not!
6
The Nature of Light Wave Theory?
  • Christian Huygens argued that light might be some
    sort of a wave motion
  • Thomas Young (1801) provided the
  • first clear demonstration of the wave
  • nature of light
  • He showed that light rays interfere
  • with each other
  • Such behavior could not be explained
  • by particles

During the nineteenth century, other developments
led to the general acceptance of the wave theory
of light
7
Light as a Wave
Plane wave
- speed of light
changes only along one direction
- wavelength
Period of oscillation (time to travel
distance of wavelength)
maximum
minimum
Frequency of light
8
Light as a Wave
  • Light is characterized by
  • its speed and
  • wavelength (or frequency )

Different frequency (wavelength) different
color of light
What is the speed of light?
9
Measurements of the Speed of Light Fizeaus
Method (1849)
  • d is the distance between the wheel and the
    mirror
  • ?t is the time for one round trip
  • Then c 2d / ?t
  • Fizeau found a value of
  • c 3.1 x 108 m/s

c 3.00 x 108 m/s
- Speed in Vacuum!
10
Speed of Light
What is the speed of light in a medium?
The speed of light in a medium is smaller than
the speed in vacuum.
  • To understand this you can think about it in a
    following way
  • The medium consists of atoms (or molecules),
    which can absorb light and then emit it,
  • so the propagation of light through the medium
    can be considered as a process of absorption and
    subsequent emission (AFTER SOME TIME )

atoms
light (free propagation)
very schematic picture
11
Speed of Light
- The speed of light in the medium
  • The properties of the medium is characterized by
    one dimensionless constant n, (it is called
    index of refraction, we will see later why)
  • which is equal to 1 for vacuum (and very close
    to 1 for air),
  • greater then 1 for all other media

12
Light in the Media
E at a given point
- The speed of light in the medium
P1
The same period (frequency) in all media, then
13
Light as a Wave
Distribution of some Field inside the wave of
frequency f

At a given time t we have sin-function of x with
initial phase, depending on t

At a given space point x we have sin-function of
t with initial phase, depending on x
14
Sin-function Constructive Interference
Amplitude
Phase (initial)
Amplitude
Amplitude
Amplitude
The phase difference between two waves should be
0 or integer number of
15
Sin-function Destructive Interference
Amplitude
Phase (initial)
Amplitude
Amplitude
Amplitude (no signal)
The phase difference between two waves should be
or plus integer number of
16
Waves Interference
Interference sum of two waves
  • In constructive interference the amplitude of
    the resultant wave is greater than that of either
    individual wave
  • In destructive interference the amplitude of the
    resultant wave is less than that of either
    individual wave

17
Waves Interference
Phase (initial)
Amplitude
Amplitude
Amplitude
Constructive Interference The phase difference
between two waves should be 0 or integer number
of
Destructive Interference The phase difference
between two waves should be or integer
number of
18
Conditions for Interference
coherent
The sources should be monochromatic (have the
same frequency)
19
  • Double-Slit Experiment
  • (interference)

  • 2. Single-Slit Diffraction
  • 3. Diffraction Grating

20
Youngs Double-Slit Experiment
  • Thomas Young first demonstrated interference in
    light waves from two sources in 1801
  • The narrow slits S1 and S2 act as sources of
    waves
  • The waves emerging from the slits originate from
    the same wave front and therefore are always in
    phase

21
Double-Slit Experiment Interference

The phase of wave 1
The phase of wave 2
Constructive Interference (bright fringe)
where n is integer
Destructive Interference (dark fringe)
where n is integer
22
Double-Slit Experiment Interference
Destructive Interference (dark fringe)
Constructive Interference (bright fringe)
23
Double-Slit Experiment Interference
  • The path difference, d, is found from the tan
    triangle
  • d x2 x1 d sin ?
  • This assumes the paths are parallel
  • Not exactly true, but a very good approximation
    if L is much greater than d

24
Double-Slit Experiment Interference
d x2 x1 d sin ?
Bright fringes (constructive interference)
d d sin ? n? n 0,
1, 2, n is called the order number
- when n 0, it is the zeroth-order maximum
- when n 1, it is called the first-order
maximum
Dark fringes (destructive interference)
d d sin ? (n ½)? n 0,
1, 2,
25
Double-Slit Experiment Interference
d x2 x1 d sin ?
The positions of the fringes can be measured
vertically from the zeroth-order maximum ? is
small and therefore the small angle approximation
tan ? sin ? can be used y L tan ? L
sin ?
  • For bright fringes
  • For dark fringes

26
Constructive Interference (bright fringe)
where n is integer
Destructive Interference (dark fringe)
where n is integer
27
Double-Slit Experiment Example
The two slits are separated by 0.150 mm, and the
incident light includes light of wavelengths
and . At what
minimal distance from the center of the screen
the bright line of the light coincides with
a bright line of the light
Bright lines
28
Double-Slit Experiment Example
Light with a wavelength of 442 nm passes through
a double-slip system that has a slip separation
d0.4 mm. Determine L so that the first dark
fringe appears directly opposite both slits.
Dark lines
29
Chapter 22
Diffraction Pattern and Interference
30
Diffraction
Diffraction Light spreads beyond the narrow path
defined by the slit into regions that would be in
shadow if light traveled in straight lines
Diffraction Pattern
Diffraction
Wrong picture if
Geometric Optics - if
Diffraction and Interference are closely
related Diffraction Patterns are due to
Interference
31
Diffraction Pattern
Diffraction
Diffraction Pattern
secondary maxima
central maximum
Diffraction
Diffraction Pattern
Diffraction Pattern is similar to Interference
Pattern
32
Huygenss Principle
33
Huygenss Principle
Huygenss Principle is a geometric construction
for determining the position of a new wave at
some point based on the knowledge of the wave
front that preceded it
  • All points on a given wave front are taken as
    point sources for the production of spherical
    secondary waves, called wavelets, which propagate
    outward through a medium with speeds
    characteristic of waves in that medium
  • After some time has passed, the new position of
    the wave front is the surface tangent to the
    wavelets

34
Single-Slip Diffraction
35
Single Slit Diffraction
  • Each portion of the slit acts as a source of
    light waves
  • Therefore, light from one portion of the slit can
    interfere with light from another portion

36
Intensity of Single-Slit Diffraction Pattern
The first minimum occurs at
or
or
37
Diffraction
The size of the spot
The size of the spot (image)
38
Diffraction Example
The source of the light emits the light with
wavelength . The diffraction
pattern is observed in the water,
. L 10m, a0.5 mm What is the size of the
spot, D ?
wavelength in the water

The size of the spot (image)
39
Chapter 22
Diffraction Grating
40
Diffraction Grating
  • The diffraction grating consists of a large
    number of equally spaced parallel slits
  • A typical grating contains several thousand lines
    per centimeter
  • The intensity of the pattern on the screen is the
    result of the combined effects of interference
    and diffraction
  • Each slit produces diffraction, and the
    diffracted beams interfere with one another to
    form the final pattern

41
N-Slit Interference Intensity Graph

Two Slits
Three Slits

For N slits, the primary maxima is N2 times
greater than that due to a single slit
42
Diffraction Grating
The condition for maxima is then The
integer m is the order number of the diffraction
pattern
43
Diffraction Grading
  • All the wavelengths are seen at m 0
  • This is called the zeroth-order maximum
  • The first-order maximum corresponds to m 1
  • Note the sharpness of the principle maxima and
    the broad range of the dark areas

44
Diffraction Grating Spectrometer
sharp peaks
  • The collimated beam is incident on the grating
  • The diffracted light leaves the gratings and the
    telescope is used to view the image
  • The wavelength can be determined by measuring the
    precise angles at which the images of the slit
    appear for the various orders

45
Diffraction Grading Example
Three discrete spectral lines occur at angles
10.090, 13.710, and 14.770 in the first order
spectrum of a grading spectrometer. If the
grading has N3600 slits per centimeter, what are
the wavelength of the light?
First order means that m1, then
Then
46
Chapter 22
Michelson Interferometer
47
Michelson Interferometer
  • A ray of light is split into two rays by the
    mirror Mo
  • The mirror is at 45o to the incident beam
  • The mirror is called a beam splitter
  • It transmits half the light and reflects the rest
  • The two rays travel separate paths L1 and L2

Maximum (constructive interference)
48
Michelson Interferometer
Glass film
The maximum with and without glass film. What
is the value of d?
Without glass film maximum (constructive
interference)
With glass film maximum (constructive
interference)
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